Apparatus and method for removing common phase error in a dvb-t/h receiver

ABSTRACT

A receiver is a Digital Video Broadcasting-Terrestrial/Handheld (DVB-T/H) receiver. The DVB-T/H receiver comprises a phase error corrector and a channel estimation and equalization element. The phase error corrector rotates a signal in accordance with an estimate of a phase error, e.g., CPE, which is determined as a function of channel state information (CSI) provided by the channel estimation and equalization element.

BACKGROUND OF THE INVENTION

The present invention generally relates to communications systems and,more particularly, to wireless systems, e.g., terrestrial broadcast,cellular, Wireless-Fidelity (Wi-Fi), satellite, etc.

Digital Video Broadcasting-Terrestrial (DVB-T) (e.g., see ETSI EN 300744 V1.4.1 (2001-01), Digital Video Broadcasting (DVB); Framingstructure, channel coding and modulation for digital terrestrialtelevision), is one of the four kinds of digital television (DTV)broadcasting standards in the world, and DVB-H is a standard forhandheld applications based on DVB-T (also referred to herein asDVB-T/H). DVB-T uses Orthogonal Frequency Division Multiplexing (OFDM)technology, i.e., DVB-T uses a form of a multi-carrier transmissioncomprising many low symbol rate sub-carriers that are orthogonal.

A DVB-T/H receiver comprises an antenna and a tuner. The antennaprovides radio frequency (RF) signals to the tuner, which is tuned to aselected frequency range, or selected channel. The tuner downconvertsthe received RF signal in the selected channel to provide either anintermediate frequency (IF) signal or a baseband signal for furtherprocessing by the DVB-T/H receiver, e.g., to recover a television (TV)program for display to a user. Typically, a tuner performsdownconversion with a mixer and a Voltage Controlled Oscillator (VCO).The VCO is an important element in the tuner. Unfortunately, the VCO isa main contributor of phase noise (PHN).

Generally, PHN is not a big problem for analog TV systems. However, forDTV systems using OFDM, the impact of PHN on receiver operation is muchmore significant. In particular, PHN introduces a common phase error(CPE), which causes a rotation of the signal constellation; and alsocreates an inter-carrier interference (ICI) term that adds to anychannel noise. As a result, both CPE and ICI interfere with demodulationof the received DVB-T signal and, therefore, removal of PHN in a DVB-T/Hreceiver is very important.

With regard to CPE, a DVB-T receiver can estimate the CPE and correctfor it by using pilots (predefined subcarriers (i.e., frequencies)having a given amplitude and phase) that are present in each OFDMsymbol. In DVB-T there are two types of pilots: scattered pilots (SP)and continual pilots (CP). The continual pilots have fixed locationswithin OFDM symbols and are used for CPE removal.

A conventional CPE removal arrangement is shown in FIGS. 1 and 2. InDVB-T there are two modes of operation, a 2K mode—corresponding to theuse of 2048 subcarriers—and an 8K mode—corresponding to the use of 8192subcarriers. In this example, it is assumed that the receiver isoperating in the 8K mode. Operation in the 2K mode is similar and notdescribed herein. The CPE removal arrangement of FIG. 1 comprises FastFourier Transform (FFT) element 105, spectrum shift element 110, CPEremoval element 115 and channel estimation and equalization (CHE)element 120. FFT element 105 processes a received baseband signal 104.The latter is provided by, e.g., a tuner (not shown) tuned to a selectedRF channel. FFT element 105 transforms received baseband signal 104 fromthe time domain to the frequency domain and provides FFT output signal106 to spectrum shift element 110. It should be noted that FFT outputsignal 106 represents complex signals having in-phase and quadraturecomponents. Typically, FFT element 105 performs butterfly calculationsas known in the art and provides reordered output data (8192 complexsamples in an 8k mode of operation). As such, spectrum shift element 110further processes FFT output signal 106 to rearrange, or shift, the FFToutput data. In particular, spectrum shift element 110 buffers one OFDMsymbol and tidies the subcarrier locations to comply with theabove-mentioned DVB-T standard and also shifts the subcarriers from [0,2π] to [−π, +π] to provide spectrum shifted signal 111. CPE removalelement 115 processes spectrum shifted signal 111 to remove any CPE(described below) and provides a CPE corrected signal 116 to CHE element120. CHE element 220 processes the CPE corrected signal 116 for (a)determining channel state information (CSI) for providing CSI signal122; and (b) equalizing the received baseband signal to compensate forany transmission channel distortion for providing equalized signal 121.As known in the art, CSI signal 122 may be used for obtaining bitmetrics for use in decoding (not shown in FIG. 1). Equalized signal 121is further processed by the receiver to, e.g., recover content conveyedtherein (audio, video, etc.) (also not shown in FIG. 1).

Turning now to FIG. 2, the operation of CPE removal element 115 is shownin more detail. CPE removal element 115 comprises: delay buffer 155, CPextractor 160, CP locations element 165, CP memory 170, complexconjugate multiplier 175, accumulator 180, phase calculator 185, phaseaccumulator and sin and cos calculator 190, and rotator (also referredto as a multiplier) 195. Delay buffer 155 stores one OFDM symbol in 8Kmode and thus provides for a one OFDM symbol time delay for determiningan estimate of the CPE. For the 8K mode of operation, the size of delaybuffer 155 is 8192×2×N bits, where N is the bit length of the data and 2represents the in-phase and quadrature components of the complexsignals. The delayed symbol is applied to rotator 195 along with a CPEestimate signal 191. Rotator 195 corrects for the CPE by rotating thedelayed symbol from delay buffer 155 in the opposite direction inaccordance with CPE estimate signal 191 to provide CPE corrected signal116.

In general, the arrangement shown in FIG. 2 operates such that CPEestimate signal 191 is determined from the autocorrelation of CPsoccurring at different points in time.

In particular, CP extractor 160 extracts the CPs from spectrum shiftedsignal 111 at particular subcarriers as defined by CP locations element165. The latter simply stores the CP locations as defined in theabove-mentioned DVB-T standard for the 8K mode of operation (e.g., seeTable 7, p. 29, of the above-mentioned DVB-T standard). The extractedCPs are provided both to CP memory 170 and complex conjugate multiplier175. Memory 170 also provides a delay of one OFDM symbol. Complexconjugate multiplier 175 multiplies the complex conjugates of CPs havingthe same frequencies but occurring at two different points in time(i.e., neighboring OFDM symbols). The resulting products are averaged(via accumulator 180) from which a phase error is calculated (via phasecalculator 185) for each OFDM symbol. Phase accumulator and sin and coscalculator 190 further accumulates the calculated phase errors for eachOFDM symbol and determines an estimate of the CPE to provide CPEestimate signal 191, which is applied to rotator 195 to correct for CPEin the signal, as described above.

SUMMARY OF THE INVENTION

We have realized that it is possible to further improve the operationand efficiency of CPE removal in an OFDM-based receiver. In particular,and in accordance with the principles of the invention, a receiverperforms phase error correction on a signal as a function of channelstate information (CSI).

In an illustrative embodiment of the invention, a receiver is a DVB-T/Hreceiver. The DVB-T/H receiver comprises a phase error corrector and achannel estimation and equalization element. The phase error correctorrotates a signal in accordance with an estimate of a phase error, e.g.,CPE, which is determined as a function of channel state information(CSI) provided by the channel estimation and equalization element.

In view of the above, and as will be apparent from reading the detaileddescription, other embodiments and features are also possible and fallwithin the principles of the invention.

BRIEF DESCRIPTION OF THE DRAWINGS

FIGS. 1 and 2 show prior art common phase error removal;

FIG. 3 shows an illustrative embodiment of an apparatus in accordancewith the principles of the invention;

FIG. 4 shows an illustrative embodiment of a portion of a receiver inaccordance with the principles of the invention;

FIG. 5 shows an illustrative embodiment of phase corrector 215 inaccordance with the principles of the invention;

FIGS. 6-14 shows an illustrative spectrum shift index table associatedwith FFT element 205;

FIGS. 15 and 16 show continual pilot (CP) location tables related tophase corrector 215, which operates in accordance with the principles ofthe invention;

FIG. 17 shows an illustrative matlab program for converting Table 3 toTable 4 in accordance with Table 1; and

FIGS. 18 and 19 show illustrative flow charts for use in a receiver inaccordance with the principles of the invention.

DETAILED DESCRIPTION

Other than the inventive concept, the elements shown in the figures arewell known and will not be described in detail. For example, other thanthe inventive concept, familiarity with Discrete Multitone (DMT)transmission (also referred to as Orthogonal Frequency DivisionMultiplexing (OFDM) or Coded Orthogonal Frequency Division Multiplexing(COFDM)) is assumed and not described herein. Also, familiarity withtelevision broadcasting, receivers and video encoding is assumed and isnot described in detail herein. For example, other than the inventiveconcept, familiarity with current and proposed recommendations for TVstandards such as NTSC (National Television Systems Committee), PAL(Phase Alternation Lines), SECAM (SEquential Couleur Avec Memoire), ATSC(Advanced Television Systems Committee) (ATSC), Digital VideoBroadcasting (DVB) and the Chinese Digital Television System (GB)20600-2006 (Digital Multimedia Broadcasting-Terrestrial/Handheld(DMB-T/H)) is assumed. Further information on DVB-T/H can be found in,e.g., ETSI EN 300 744 V1.4.1 (2001-01), Digital Video Broadcasting(DVB); Framing structure, channel coding and modulation for digitalterrestrial television; and ETSI EN 302 304 V1.1.1 (2004-11), DigitalVideo Broadcasting (DVB); Transmission System for Handheld Terminals(DVB-H). Likewise, other than the inventive concept, other transmissionconcepts such as eight-level vestigial sideband (8-VSB), QuadratureAmplitude Modulation (QAM), and receiver components such as aradio-frequency (RF) front-end, or receiver section, such as a low noiseblock, tuners, and down converters; along with fast fourier transform(FFT) elements, spectrum shifters, channel state information (CSI)estimators, equalizers, demodulators, correlators, leak integrators andsquarers is assumed. Further, other than the inventive concept,familiarity with processing signals, such as forming channel stateinformation, is assumed and not described herein. Similarly, other thanthe inventive concept, formatting and encoding methods (such as MovingPicture Expert Group (MPEG)-2 Systems Standard (ISO/IEC 13818-1)) forgenerating transport bit streams are well-known and not describedherein. It should also be noted that the inventive concept may beimplemented using conventional programming techniques (such asrepresented by matlab), which, as such, will not be described herein. Inthis regard, the embodiments described herein may be implemented in theanalog or digital domains. Further, those skilled in the art wouldrecognize that some of the processing may involve complex signal pathsas necessary. Finally, like-numbers on the figures represent similarelements.

Referring now to FIG. 3, an illustrative embodiment of a device 10 inaccordance with the principles of the invention is shown. Device 10 isrepresentative of any processor-based platform, e.g., a PC, a server, aset-top box, a personal digital assistant (PDA), a cellular telephone, amobile digital television (DTV), a DTV, etc. In this regard, device 10includes one, or more, processors with associated memory (not shown) andalso comprises receiver 15. The latter receives a broadcast signal 1 viaan antenna (not shown)). For the purposes of this example, it is assumedthat broadcast signal 1 is representative of a DVB-T/H service, i.e., aDTV transport stream, which includes video, audio and/or systeminformation for at least one TV channel and that broadcast signal 1conveys this information using at least a multi-carrier modulation suchas orthogonal frequency division multiplexing (OFDM). However, theinventive concept is not so limited and is applicable to any receiverthat processes OFDM-based signals. In accordance with the principles ofthe invention, receiver 15 performs phase error correction on a signalas a function of channel state information (CSI) and recovers therefromoutput signal 16 for application to an output device 20, which may, ormay not, be a part of device 10 as represented in dashed-line form. Inthe context of this example, output device 20 is a display that allows auser to view a selected TV program.

Turning now to FIG. 4, an illustrative portion of receiver 15 is shown.Only that portion of receiver 15 relevant to the inventive concept isshown. Other than the inventive concept, the elements shown in FIG. 4are known and not described herein. In this example, it is assumed thatreceiver 15 is operating in the 2K mode. It should be noted thatoperation in the 8K mode is similar and, as such, not described herein.Receiver 15 comprises downconverter 200, fast fourier transform (FFT)element 205, spectrum shift element 210, phase corrector 215 and channelestimation and equalizer (CHE) 220. In addition, receiver 15 is aprocessor-based system and includes one, or more, processors andassociated memory as represented by processor 290 and memory 295 shownin the form of dashed boxes in FIG. 4. In this context, computerprograms, or software, are stored in memory 295 for execution byprocessor 290. The latter is representative of one, or more,stored-program control processors and these do not have to be dedicatedto the receiver function, e.g., processor 290 may also control otherfunctions of receiver 15. For example, if receiver 15 is a part of alarger device, processor 290 may control other functions of this device.Memory 295 is representative of any storage device, e.g., random-accessmemory (RAM), read-only memory (ROM), etc.; may be internal and/orexternal to receiver 15; and is volatile and/or non-volatile asnecessary.

FFT element 205 processes a received baseband signal 204. The latter isprovided by downconverter 200, which is a part of a tuner (not shown) ofreceiver 15 tuned to a selected RF channel associated with broadcastsignal 1 of FIG. 3. FFT element 205 transforms received baseband signal204 from the time domain to the frequency domain and provides FFT outputsignal 206 to spectrum shift element 210. It should be noted that FFToutput signal 206 represents complex signals having in-phase andquadrature components. Typically, FFT element 205 performs butterflycalculations as known in the art and provides reordered output data(2048 complex samples in an 8k mode of operation). As such, spectrumshift element 210 further processes FFT output signal 206 to rearrange,or shift, the FFT output data. In particular, spectrum shift element 210buffers one OFDM symbol and tidies the subcarrier locations to complywith the above-mentioned DVB-T standard and also shifts the subcarriersfrom [0, 2π] to [−π, +π] to provide spectrum shifted signal 211. Inaccordance with the principles of the invention (described furtherbelow), phase corrector 215 processes spectrum shifted signal 211 toremove any phase offsets, e.g., those associated with CPE, and providesa phase corrected signal 216 to CHE element 220. CHE element 220processes the phase corrected signal 216 for (a) determining channelstate information (CSI) for providing CSI signal 222; and (b) equalizingthe received baseband signal to compensate for any transmission channeldistortion for providing equalized signal 221. As known in the art, CSIsignal 222 may be used for obtaining bit metrics for use in decoding(not shown in FIG. 4). However, and in accordance with the principles ofthe invention, CSI is also used to correct for phase error. Finally,equalized signal 221 is further processed (not shown) by receiver 15 to,e.g., recover content conveyed therein (audio, video, etc.) (e.g., seeoutput signal 16 of FIG. 3).

Attention should now be directed to FIG. 5, which shows an illustrativeembodiment of phase corrector 215 in accordance with the principles ofthe invention. Phase corrector 215 comprises CP correction element 305,pre-shifted CP location element 310, memory 315, complex conjugatemultiplier 320, accumulator 325, phase calculator and sin and coscalculator 330 and rotator (or multiplier) 335. Other than the inventiveconcept, the elements shown in FIG. 5 are known and not describedherein. At the outset, it should be noted that the inventive concepttakes advantage of the fact that spectrum shift element 210 alreadybuffers an OFDM symbol. In particular, and as can be observed from FIG.5, phase corrector 215 uses FFT output signal 206 for estimating thephase error and corrects spectrum shifted signal 211 for the phaseerror. Thus, an advantage of the invention is that it can be implementedin such a way that a receiver requires less memory—and less cost.

With regard to correcting for the phase error, and as mentioned justabove, phase corrector 215 corrects the phase of spectrum shifted signal211. In particular, spectrum shifted signal 211 is applied to rotator335 along with a phase error estimate signal 331. Rotator 335 correctsfor the phase error, e.g., the CPE, by rotating spectrum shifted signal211 in the opposite direction in accordance with phase error estimatesignal 331 to provide phase corrected signal 216. Ideally, phase errorestimate signal 331 corrects for substantially all of the phase error,i.e., at least some, if not all, of the phase error is removed from thesignal via rotator 335. As used herein, any references to removing phaseerror means to at least reduce, if not eliminate, the phase error.

With regard to estimating the phase error, and as mentioned just above,phase corrector 215 uses FFT output signal 206 for estimating the phaseerror. However, as noted earlier, FFT element 205 of FIG. 4 performsbutterfly calculations as known in the art and provides reordered outputdata (2048 complex samples in a 2k mode of operation). As a result, anyuse of the CP locations as defined in DVB-T with respect to FFT outputsignal 206 need to be further adjusted to take into account this FFTreordering. Thus, pre-shifted CP location element 310 stores pre-shiftedCP values, which are shown in Table Four of FIG. 16. These CP values are“pre-shifted” in the sense that this is the location of the CPs asdefined in DVB-T but with respect to the ordering provided by FFTelement 205. In particular, for an FFT, such as represented by FFTelement 205 in the 2k mode of operation, an associated spectrum shiftindex table is known. An illustrative spectrum shift index table for a2k mode of operation is shown in Table One in FIGS. 6-14. For example,for a sample index, k, where 1≦k≦2048, FIG. 6 illustrates the first 240spectrum shift frequency values for the first 240 k values of FFTelement 205. In particular, at k=1, the associated spectrum shift indexvalue has a frequency value of 1024; while at k=16, the associatedspectrum shift index value has a frequency value of 832 and at k=240,the associated spectrum shift index value has a frequency value of 884,and so on, through the spectrum shift frequency value of 1023 at k=2048shown in FIG. 14. Thus, in view of Table One, it is possible to shiftthe CP locations as defined in DVB-T to their location in FFT outputsignal 206. This is illustrated in Tables Two, Three and Four of FIGS.15 and 16.

Table Two of FIG. 15 simply shows the subcarrier locations of the 45 CPsas currently defined in DVB-T in the 2k mode of operation. For example,see p. Table 7, p. 29, of the above-mentioned DVB-T standard. Thus, asshown in Table Two, the first CP occurs as a subcarrier value of 0, etc.However, in DVB-T, although there are 2048 subcarriers, only 1705subcarriers are actually active. There are 172 inactive subcarrierspreceding the active subcarriers and 171 inactive subcarriers followingthe active subcarriers. This is illustrated by OFDM symbol 81 of FIG. 15(not to scale). In this regard, since phase corrector 215 is estimatingthe phase error from FFT output signal 206—and not spectrum shiftedsignal 211—all of the 2048 subcarriers must be taken into account.Therefore, Table Two must first be translated into Table Three, whereeach of the values of Table Two are shifted by 172. As illustrated bydotted line 91, the active subcarrier CP located at 0 actuallycorresponds to subcarrier 172, when the inactive subcarriers are takeninto account. From the values of Table Three, and given the spectrumshift index values shown in Table One of FIGS. 6-14, it is possible tonow calculate the pre-shifted locations of the all the CPs, i.e., theirlocations in FFT output signal 206. The results of this calculation areshown in Table 4 of FIG. 16 for the 2k mode of operation for theforty-five CPs. For example, the CP located at subcarrier 976 isassociated with sample number 63 (starting from 0), as illustrated bydotted line 92. This can be verified from Table 1, which starts fromk=1, where it can be observed from FIG. 6 that k=64 is associated withsubcarrier 976. Likewise, and as illustrated by dotted line 93, the CPlocated at subcarrier 1141 is sample number 744 (again, starting from 0)(e.g., see Table 1, FIG. 9, k=745). Turning briefly to FIG. 17, anillustrative matlab program for converting Table 2 into Table 3 and thenforming Table 4 from Table 3 in accordance with Table 1 is shown. As aresult, pre-shifted CP location element 310 stores the CP locations asdefined in Table Four of FIG. 16.

For each CP, corresponding sample values of the associated pre-shiftedCP are provided to CP correction element 305 from memory 310. (It shouldbe recalled that each CP has a given amplitude and phase.) CP correctionelement 305 modifies, or corrects, each CP value, e.g., a phase value,in accordance with the CSI information provided from CHE 220 via CSIsignal 222. Other than the inventive concept, CSI information is knownin the art and not described herein. Generally speaking, the CSIinformation takes into account the reliability of each of thesubcarriers as affected by the transmission channel. In accordance withthe principles of the invention, by correcting the pre-shifted CP valuesto take into account the channel response information, the channeleffects can be eliminated during the phase error removal processing,and, as a result, it is possible to obtain good estimation performance.CP correction element 305 provides the resulting CSI-CP sequence 306 tomemory 315 for storage. Complex conjugate multiplier 320 multiplies thecomplex conjugates of the stored CSI-CP sequence (from memory 315) withFFT output signal 206. The resulting products are averaged (viaaccumulator 325) for each OFDM symbol. Phase calculator and sin and coscalculator 330 further calculates an estimate of the phase error andgenerates in-phase and quadrature values to provide phase error estimatesignal 331, which is applied to rotator 335 to correct for phase errorin the signal. It should be observed that the phase error correctionelement illustrated in FIG. 5 cross correlates the CSI-CP sequence withFFT output signal 206 (versus the auto correlation technique betweentime shifted samples of the same signal as illustrated in theconventional technique of FIG. 2).

Turning now to FIGS. 18 and 19, illustrative flow charts for use in areceiver for performing phase error correction in accordance with theprinciples of the invention are shown. In step 405, a receiverdownconverts a received broadcast signal (e.g., receiver 15 of FIG. 3).In step 410, the receiver estimates the phase error in the downconvertedsignal in accordance with the principles of the invention. And, in step415, the receiver corrects the downconverted signal for the estimatedphase error.

Step 410 of FIG. 18 is shown in more detail in the flow chart of FIG.19. In step 505, the receiver retrieves pre-shifted CP locations (e.g.,from a memory as represented by element 310 of FIG. 5). In step 510, thereceiver corrects the pre-shifted CPs with CSI to provide a CSI-CPsequence, i.e., a sequence of corrected pre-shifted CP values. In step515, the CSI-CP sequence is cross-correlated with the FFT output signal(representative of the downconverted signal), the results of which areused to determine an estimate of the phase error in step 520.

As described above, and in accordance with the principles of theinvention, a receiver performs phase error correction on a signal, e.g.,as a result of CPE, as a function of channel state information (CSI). Inthis regard, at least two advantages can be observed in comparison tothe conventional CPE removal element 115 of FIG. 2. First, as comparedto FIG. 2, a separate delay buffer 155 for the OFDM symbol is notneeded. Thus, the inventive concept significantly reduces memoryrequirements, especially for the 8k mode of operation. Second, ascompared to FIG. 2, the phase accumulator function of element 190 is notneeded. Thus, the inventive concept further simplifies phase errorprocessing. However, the inventive concept is not so limited and thoseskilled in the art can construct phase error removal elements inaccordance with the principles of the invention without taking advantageof these benefits, e.g., by including an OFDM symbol buffer. Further, itshould be noted that the inventive concept is not limited to correctingfor just one type of phase error such as CPE. In addition, it should benoted that although the inventive concept was illustrated in the contextof a DTV-T broadcast signal, the inventive concept is not so limited andis applicable to other types of receivers that perform OFDM reception,such as a software defined radio receiver, a DMB-T/H receiver, etc.

In view of the above, the foregoing merely illustrates the principles ofthe invention and it will thus be appreciated that those skilled in theart will be able to devise numerous alternative arrangements which,although not explicitly described herein, embody the principles of theinvention and are within its spirit and scope. For example, althoughillustrated in the context of separate functional elements, thesefunctional elements may be embodied in one, or more, integrated circuits(ICs). Similarly, although shown as separate elements, any or all of theelements may be implemented in a stored-program-controlled processor,e.g., a digital signal processor, which executes associated software,e.g., corresponding to one, or more, of the steps shown in, e.g., FIGS.18-19, etc. Further, the principles of the invention are applicable toother types of communications systems, e.g., satellite,Wireless-Fidelity (Wi-Fi), cellular, etc. Indeed, the inventive conceptis also applicable to stationary or mobile receivers. It is therefore tobe understood that numerous modifications may be made to theillustrative embodiments and that other arrangements may be devisedwithout departing from the spirit and scope of the present invention asdefined by the appended claims.

1. A method for use in a receiver, the method comprising: receiving asignal, the signal representing an orthogonal frequency divisionmultiplexed (OFDM) signal; and performing phase error correction on thesignal as a function of channel state information (CSI) for providing aphase corrected signal.
 2. The method of claim 1, further comprising:downconverting a received radio frequency signal for providing adownconverted signal; performing a fast fourier transform (FFT) on thedownconverted signal for providing an FFT output signal; and spectrumshifting the FFT output signal for providing the signal.
 3. The methodof claim 2, wherein the performing phase error correction step furthercomprises: determining a phase error from the FFT output signal as afunction of the CSI; and correcting a phase of the signal in accordancewith the determined phase error.
 4. The method of claim 3, wherein thecorrecting step includes the step of: rotating the signal in accordancewith the determined phase error.
 5. The method of claim 3, wherein thephase error is representative of a common phase error.
 6. The method ofclaim 1, further comprising the steps of: processing the phase correctedsignal for providing the CSI information.
 7. The method of claim 1,further comprising the steps of: equalizing the phase corrected signalto provide an equalized signal in such a way that CSI information isgenerated.
 8. The method of claim 1 wherein the performing phase errorcorrection step further comprises: modifying pre-shifted continualpilots (CPs) as a function of the CSI to provide a pre-shifted CP-CSIsequence; cross-correlating FFT output data representative of the signalwith the pre-shifted CP-CSI sequence to provide cross-correlationresults; determining a phase error from the cross-correlation results;and correcting a phase of the signal in accordance with the determinedphase error.
 9. The method of claim 8, wherein the correcting stepincludes the step of: rotating the signal in accordance with thedetermined phase error.
 10. Apparatus comprising: a downconverter forproviding a downconverted signal; and a processor operative on a firstsignal that is representative of a fast fourier transform of thedownconverted signal for estimating a phase error as a function ofchannel state information (CSI) and for correcting a phase of a secondsignal in accordance with the estimated phase error, wherein the secondsignal is representative of a spectrum shifted version of the firstsignal.
 11. The apparatus of claim 10, further comprising: a memory forstoring locations of pre-shifted continual pilots (CPs) in the firstsignal; wherein the processor (a) forms modified CPs corresponding tothe stored locations in accordance with the CSI and (b) cross correlatesthe modified CPs with the first signal for estimating the phase error.12. The apparatus of claim 10, wherein The processor corrects the phaseof the second signal by rotating the second signal in accordance withthe estimated phase error.
 13. The apparatus of claim 10, wherein theestimated phase error is representative of a common phase error.
 14. Theapparatus of claim 10, wherein the processor processes the second signalfor determining the CSI information.
 15. The apparatus of claim 10,wherein the processor equalizes the second signal in such a way that CSIinformation is generated.
 16. Apparatus comprising: a fast fouriertransform (FFT) for providing an FFT output signal comprising a numberof samples; a spectrum shifter for reordering the samples in the FFToutput signal to provide a spectrum shifted signal; and a phasecorrector responsive to channel state information (CSI) for estimating aphase error from the FFT output signal and for correcting a phase of thespectrum shifted signal in accordance with the estimated phase error.17. The apparatus of claim 16, wherein the phase error is representativeof a common phase error.
 18. The apparatus of claim 16, wherein thephase corrector comprises: a memory for storing locations of pre-shiftedcontinual pilots (CPs) in the FFT output signal; a memory for storingmodified pre-shifted CPs, wherein the modified pre-shifted CPs arederived from the pre-shifted CPs and CSI; and a cross correlator for usein estimating the phase error, wherein the cross correlator crosscorrelates the modified pre-shifted CPs with the FFT output signal. 19.The apparatus of claim 18, further comprising: a rotator for correctingthe phase of the spectrum shifted signal in accordance with theestimated phase error.
 20. The apparatus of claim 16, furthercomprising: an equalizer for equalizing the phase corrected spectrumshifted signal and for providing the CSI.